Δ34S

Last updated

The δ34S (pronounced delta 34 S) value is a standardized method for reporting measurements of the ratio of two stable isotopes of sulfur, 34S:32S, in a sample against the equivalent ratio in a known reference standard. The most commonly used standard is Vienna-Canyon Diablo Troilite (VCDT). Results are reported as variations from the standard ratio in parts per thousand, per mil or per mille, using the ‰ symbol. Heavy and light sulfur isotopes fractionate at different rates and the resulting δ34S values, recorded in marine sulfate or sedimentary sulfides, have been studied and interpreted as records of the changing sulfur cycle throughout the earth's history.

Contents

Calculation

Of the 25 known isotopes of sulfur, four are stable. [1] In order of their abundance, those isotopes are 32S (94.93%), 34S (4.29%), 33S (0.76%), and 36S (0.02%). [2] The δ34S value refers to a measure of the ratio of the two most common stable sulfur isotopes, 34S:32S, as measured in a sample against that same ratio as measured in a known reference standard. The lowercase delta character is used by convention, to be consistent with use in other areas of stable isotope chemistry. [3] That value can be calculated in per mil (‰, parts per thousand) as: [4]

Less commonly, if the appropriate isotope abundances are measured, similar formulae can be used to quantify ratio variations between 33S and 32S, and 36S and 32S, reported as δ33S and δ36S, respectively. [5]

Reference standard

Troilite from the Canyon Diablo meteorite was the first reference standard for d S. Canyon Diablo meteorite by Matthew Bisanz.JPG
Troilite from the Canyon Diablo meteorite was the first reference standard for δ S.

Sulfur from meteorites was determined in the early 1950s to be an adequate reference standard because it exhibited a small variability in isotopic ratios. [6] It was also believed that because of their extraterrestrial provenances, meteors represented primordial terrestrial isotopic conditions. [7] During a meeting of the National Science Foundation in April 1962, troilite from the Canyon Diablo meteorite found in Arizona, US, was established as the standard with which δ34S values (and other sulfur stable isotopic ratios) could be calculated. [6] [8] Known as Canyon Diablo Troilite (CDT), the standard was established as having a 32S:34S ratio of 22.220 and was used for around three decades. [6] In 1993, the International Atomic Energy Agency (IAEA) established a new standard, Vienna-CDT (VCDT), based on artificially prepared silver sulfide (IAEA-S-1) that was defined to have a δ34SVCDT value of −0.3‰. [8] In 1994, the original CDT material was found not to be isotopically homogeneous, with internal variations as great as 0.4‰, confirming its unsuitability as a reference standard. [6]

Causes of variations

d SVCDT values for several geologic reservoirs Terrestrial d34S values.jpg
δ SVCDT values for several geologic reservoirs

Two mechanisms of fractionation occur that alter sulfur stable isotope ratios: kinetic effects, especially due to the metabolism of sulfate-reducing bacteria, and isotope exchange reactions that occur between sulfide phases based on temperature. [9] With VCDT as the reference standard, natural δ34S value variations have been recorded between 72‰ and +147‰. [10] [11]

The presence of sulfate-reducing bacteria, which reduce sulfate (SO2−
4) to hydrogen sulfide (H2S), has played a significant role in the oceanic δ34S value throughout the earth's history. Sulfate-reducing bacteria metabolize 32S more readily than 34S, resulting in an increase in the value of the δ34S in the remaining sulfate in the seawater. [7] Archean pyrite found in barite in the Warrawoona Group, Western Australia, with sulfur fractionations as great as 21.1‰ hint at the presence of sulfate-reducers as early as 3,470  million years ago. [12]

It is now better known that the degree of isotope fractionation during microbial sulfate reduction depends on the cell-specific sulfate reduction rate of the sulfate-reducing microorganism. [13] [14] The relative extent of sulfur isotope fractionating activities, including sulfate reduction, sulfide reoxidation and disproportionation, determines the isotopic compositions of the minerals or fluid measured. [15] Other than microbial activities and environmental conditions, isotopic compositions also change due to diffusion, accumulation and mixing after burial. [16] [17] [15]

The δ34S value, recorded by sulfate in marine evaporites, can be used to chart the sulfur cycle throughout earth's history. [7] [4] The Great Oxygenation Event around 2,400  million years ago altered the sulfur cycle radically, as increased atmospheric oxygen permitted an increase in the mechanisms that could fractionate sulfur isotopes, leading to an increase in the δ34S value from ~0‰ pre-oxygenation. Approximately 700  million years ago, the δ34S values in seawater sulfates began to vary more and those in sedimentary sulfates grew more negative. Researchers have interpreted this excursion as indicative of an increase in water column oxygenation with continued periods of anoxia in the deepest waters. Modern seawater sulfate δ34S values are consistently 21.0 ± 0.2‰ across the world's oceans, while sedimentary sulfides vary widely. Seawater sulfate δ34S and δ18O values exhibit similar trends not seen in sedimentary sulfide minerals. [7]

See also

Related Research Articles

<span class="mw-page-title-main">Sulfur</span> Chemical element with atomic number 16 (S)

Sulfur (also spelled sulphur in British English) is a chemical element; it has symbol S and atomic number 16. It is abundant, multivalent and nonmetallic. Under normal conditions, sulfur atoms form cyclic octatomic molecules with the chemical formula S8. Elemental sulfur is a bright yellow, crystalline solid at room temperature.

<span class="mw-page-title-main">Isotope analysis</span> Analytical technique used to study isotopes

Isotope analysis is the identification of isotopic signature, abundance of certain stable isotopes of chemical elements within organic and inorganic compounds. Isotopic analysis can be used to understand the flow of energy through a food web, to reconstruct past environmental and climatic conditions, to investigate human and animal diets, for food authentification, and a variety of other physical, geological, palaeontological and chemical processes. Stable isotope ratios are measured using mass spectrometry, which separates the different isotopes of an element on the basis of their mass-to-charge ratio.

Isotope geochemistry is an aspect of geology based upon the study of natural variations in the relative abundances of isotopes of various elements. Variations in isotopic abundance are measured by isotope-ratio mass spectrometry, and can reveal information about the ages and origins of rock, air or water bodies, or processes of mixing between them.

<span class="mw-page-title-main">Canyon Diablo (meteorite)</span> Iron meteorite from Meteor Crater used as sulfur isotopic reference material

The Canyon Diablo meteorite refers to the many fragments of the asteroid that created Meteor Crater, Arizona, United States. Meteorites have been found around the crater rim, and are named for nearby Canyon Diablo, which lies about three to four miles west of the crater.

In chemistry, disproportionation, sometimes called dismutation, is a redox reaction in which one compound of intermediate oxidation state converts to two compounds, one of higher and one of lower oxidation state. The reverse of disproportionation, such as when a compound in an intermediate oxidation state is formed from precursors of lower and higher oxidation states, is called comproportionation, also known as symproportionation.

<span class="mw-page-title-main">Troilite</span> Rare iron sulfide mineral: FeS

Troilite is a rare iron sulfide mineral with the simple formula of FeS. It is the iron-rich endmember of the pyrrhotite group. Pyrrhotite has the formula Fe(1-x)S which is iron deficient. As troilite lacks the iron deficiency which gives pyrrhotite its characteristic magnetism, troilite is non-magnetic.

<span class="mw-page-title-main">Sulfur cycle</span> Biogeochemical cycle of sulfur

The important sulfur cycle is a biogeochemical cycle in which the sulfur moves between rocks, waterways and living systems. It is important in geology as it affects many minerals and in life because sulfur is an essential element (CHNOPS), being a constituent of many proteins and cofactors, and sulfur compounds can be used as oxidants or reductants in microbial respiration. The global sulfur cycle involves the transformations of sulfur species through different oxidation states, which play an important role in both geological and biological processes. Steps of the sulfur cycle are:

Sulfur (16S) has 23 known isotopes with mass numbers ranging from 27 to 49, four of which are stable: 32S (95.02%), 33S (0.75%), 34S (4.21%), and 36S (0.02%). The preponderance of sulfur-32 is explained by its production from carbon-12 plus successive fusion capture of five helium-4 nuclei, in the so-called alpha process of exploding type II supernovas.

An isotopic signature is a ratio of non-radiogenic 'stable isotopes', stable radiogenic isotopes, or unstable radioactive isotopes of particular elements in an investigated material. The ratios of isotopes in a sample material are measured by isotope-ratio mass spectrometry against an isotopic reference material. This process is called isotope analysis.

In geochemistry, paleoclimatology and paleoceanography δ18O or delta-O-18 is a measure of the deviation in ratio of stable isotopes oxygen-18 (18O) and oxygen-16 (16O). It is commonly used as a measure of the temperature of precipitation, as a measure of groundwater/mineral interactions, and as an indicator of processes that show isotopic fractionation, like methanogenesis. In paleosciences, 18O:16O data from corals, foraminifera and ice cores are used as a proxy for temperature.

<span class="mw-page-title-main">Canfield ocean</span> Hypothetical middle to late Proterozoic ocean composition

The Canfield Ocean model was proposed by geochemist Donald Canfield to explain the composition of the ocean in the middle to late Proterozoic.

<span class="mw-page-title-main">Stable isotope ratio</span> Ratio of two stable isotopes

The term stable isotope has a meaning similar to stable nuclide, but is preferably used when speaking of nuclides of a specific element. Hence, the plural form stable isotopes usually refers to isotopes of the same element. The relative abundance of such stable isotopes can be measured experimentally, yielding an isotope ratio that can be used as a research tool. Theoretically, such stable isotopes could include the radiogenic daughter products of radioactive decay, used in radiometric dating. However, the expression stable-isotope ratio is preferably used to refer to isotopes whose relative abundances are affected by isotope fractionation in nature. This field is termed stable isotope geochemistry.

Isotopic reference materials are compounds with well-defined isotopic compositions and are the ultimate sources of accuracy in mass spectrometric measurements of isotope ratios. Isotopic references are used because mass spectrometers are highly fractionating. As a result, the isotopic ratio that the instrument measures can be very different from that in the sample's measurement. Moreover, the degree of instrument fractionation changes during measurement, often on a timescale shorter than the measurement's duration, and can depend on the characteristics of the sample itself. By measuring a material of known isotopic composition, fractionation within the mass spectrometer can be removed during post-measurement data processing. Without isotope references, measurements by mass spectrometry would be much less accurate and could not be used in comparisons across different analytical facilities. Due to their critical role in measuring isotope ratios, and in part, due to historical legacy, isotopic reference materials define the scales on which isotope ratios are reported in the peer-reviewed scientific literature.

Euxinia or euxinic conditions occur when water is both anoxic and sulfidic. This means that there is no oxygen (O2) and a raised level of free hydrogen sulfide (H2S). Euxinic bodies of water are frequently strongly stratified; have an oxic, highly productive, thin surface layer; and have anoxic, sulfidic bottom water. The word "euxinia" is derived from the Greek name for the Black Sea (Εὔξεινος Πόντος (Euxeinos Pontos)) which translates to "hospitable sea". Euxinic deep water is a key component of the Canfield ocean, a model of oceans during part of the Proterozoic eon (a part specifically known as the Boring Billion) proposed by Donald Canfield, an American geologist, in 1998. There is still debate within the scientific community on both the duration and frequency of euxinic conditions in the ancient oceans. Euxinia is relatively rare in modern bodies of water, but does still happen in places like the Black Sea and certain fjords.

Carbonate-associated sulfates (CAS) are sulfate species found in association with carbonate minerals, either as inclusions, adsorbed phases, or in distorted sites within the carbonate mineral lattice. It is derived primarily from dissolved sulfate in the solution from which the carbonate precipitates. In the ocean, the source of this sulfate is a combination of riverine and atmospheric inputs, as well as the products of marine hydrothermal reactions and biomass remineralisation. CAS is a common component of most carbonate rocks, having concentrations in the parts per thousand within biogenic carbonates and parts per million within abiogenic carbonates. Through its abundance and sulfur isotope composition, it provides a valuable record of the global sulfur cycle across time and space.

<span class="mw-page-title-main">Microbial oxidation of sulfur</span>

Microbial oxidation of sulfur is the oxidation of sulfur by microorganisms to build their structural components. The oxidation of inorganic compounds is the strategy primarily used by chemolithotrophic microorganisms to obtain energy to survive, grow and reproduce. Some inorganic forms of reduced sulfur, mainly sulfide (H2S/HS) and elemental sulfur (S0), can be oxidized by chemolithotrophic sulfur-oxidizing prokaryotes, usually coupled to the reduction of oxygen (O2) or nitrate (NO3). Anaerobic sulfur oxidizers include photolithoautotrophs that obtain their energy from sunlight, hydrogen from sulfide, and carbon from carbon dioxide (CO2).

The sulfate-methane transition zone (SMTZ) is a zone in oceans, lakes, and rivers typically found below the sediment surface in which sulfate and methane coexist. The formation of a SMTZ is driven by the diffusion of sulfate down the sediment column and the diffusion of methane up the sediments. At the SMTZ, their diffusion profiles meet and sulfate and methane react with one another, which allows the SMTZ to harbor a unique microbial community whose main form of metabolism is anaerobic oxidation of methane (AOM). The presence of AOM marks the transition from dissimilatory sulfate reduction to methanogenesis as the main metabolism utilized by organisms.

Tanja Bosak is a Croatian-American experimental geobiologist who is currently an associate professor in the Earth, Atmosphere, and Planetary Science department at the Massachusetts Institute of Technology. Her awards include the Subaru Outstanding Woman in Science Award from the Geological Society of America (2007), the James B. Macelwane Medal from the American Geophysical Union (2011), and was elected an AGU fellow (2011). Bosak is recognized for her work understanding stromatolite genesis, in addition to her work in broader geobiology and geochemistry.

Trace metal stable isotope biogeochemistry is the study of the distribution and relative abundances of trace metal isotopes in order to better understand the biological, geological, and chemical processes occurring in an environment. Trace metals are elements such as iron, magnesium, copper, and zinc that occur at low levels in the environment. Trace metals are critically important in biology and are involved in many processes that allow organisms to grow and generate energy. In addition, trace metals are constituents of numerous rocks and minerals, thus serving as an important component of the geosphere. Both stable and radioactive isotopes of trace metals exist, but this article focuses on those that are stable. Isotopic variations of trace metals in samples are used as isotopic fingerprints to elucidate the processes occurring in an environment and answer questions relating to biology, geochemistry, and medicine.

Sulfur isotope biogeochemistry is the study of the distribution of sulfur isotopes in biological and geological materials. In addition to its common isotope, 32S, sulfur has three rare stable isotopes: 34S, 36S, and 33S. The distribution of these isotopes in the environment is controlled by many biochemical and physical processes, including biological metabolisms, mineral formation processes, and atmospheric chemistry. Measuring the abundance of sulfur stable isotopes in natural materials, like bacterial cultures, minerals, or seawater, can reveal information about these processes both in the modern environment and over Earth history.

References

  1. Audi G, Bersillon O, Blachot J, Wapstra AH (December 2003). "The NUBASE evaluation of nuclear and decay properties". Nuclear Physics A . 729 (1): 3–128. Bibcode:2003NuPhA.729....3A. CiteSeerX   10.1.1.692.8504 . doi:10.1016/j.nuclphysa.2003.11.001. Closed Access logo transparent.svg
  2. Hoefs 2009, p. 71.
  3. Cook PG, Herczeg AL, eds. (2000). Environmental Tracers in Subsurface Hydrology (PDF). New York City: Springer Science+Business Media. p. 511. doi:10.1007/978-1-4615-4557-6. ISBN   978-1-4615-4557-6.
  4. 1 2 Canfield DE (2001). "Biogeochemistry of Sulfur Isotopes". Reviews in Mineralogy and Geochemistry . 43 (1): 607–636. Bibcode:2001RvMG...43..607C. doi:10.2138/gsrmg.43.1.607. Closed Access logo transparent.svg
  5. Whitehouse MJ (March 2013). "Multiple Sulfur Isotope Determination by SIMS: Evaluation of Reference Sulfides for Δ33S with Observations and a Case Study on the Determination of Δ36S". Geostandards and Geoanalytical Research . 37 (1): 19–33. doi:10.1111/j.1751-908X.2012.00188.x. S2CID   95283077. Closed Access logo transparent.svg
  6. 1 2 3 4 Beaudoin G, Taylor BE, Rumble III D, Thiemens M (October 1994). "Variations in the sulfur isotope composition of troilite from the Cañon Diablo iron meteorite". Geochimica et Cosmochimica Acta . 58 (19): 4253–4255. Bibcode:1994GeCoA..58.4253B. doi:10.1016/0016-7037(94)90277-1. Closed Access logo transparent.svg
  7. 1 2 3 4 Seal II RR (2006). "Sulfur Isotope Geochemistry of Sulfide Minerals". Reviews in Mineralogy and Geochemistry . 61 (1): 633–677. Bibcode:2006RvMG...61..633S. doi:10.2138/rmg.2006.61.12. Closed Access logo transparent.svg
  8. 1 2 Hoefs 2009, p. 72.
  9. Hoefs 2009, pp. 73, 77.
  10. Lever MA, Rouxel O, Alt JC, Shimizu N, Ono S, Coggon RM, et al. (March 2013). "Evidence for microbial carbon and sulfur cycling in deeply buried ridge flank basalt". Science. 339 (6125): 1305–1308. Bibcode:2013Sci...339.1305L. doi:10.1126/science.1229240. PMID   23493710. S2CID   10728606. Closed Access logo transparent.svg
  11. Drake H, Roberts NM, Reinhardt M, Whitehouse M, Ivarsson M, Karlsson A, et al. (June 2021). "Biosignatures of ancient microbial life are present across the igneous crust of the Fennoscandian shield". Communications Earth & Environment. 2 (1): 1–13. doi: 10.1038/s43247-021-00170-2 .
  12. Shen Y, Buick R, Canfield DE (March 2001). "Isotopic evidence for microbial sulphate reduction in the early Archaean era". Nature. 410 (6824): 77–81. Bibcode:2001Natur.410...77S. doi:10.1038/35065071. PMID   11242044. S2CID   25375808. Closed Access logo transparent.svg
  13. Wing BA, Halevy I (December 2014). "Intracellular metabolite levels shape sulfur isotope fractionation during microbial sulfate respiration". Proceedings of the National Academy of Sciences of the United States of America. 111 (51): 18116–18125. Bibcode:2014PNAS..11118116W. doi: 10.1073/pnas.1407502111 . PMC   4280625 . PMID   25362045.
  14. Wenk CB, Wing BA, Halevy I (October 2017). "Electron carriers in microbial sulfate reduction inferred from experimental and environmental sulfur isotope fractionations". The ISME Journal. 12 (2): 495–507. doi:10.1038/ismej.2017.185. PMC   5776465 . PMID   29087380.
  15. 1 2 Tsang MY, Wortmann UG (July 2022). "Sulfur isotope fractionation derived from reaction-transport modelling in the Eastern Equatorial Pacific". Journal of the Geological Society. 179 (5). Bibcode:2022JGSoc.179...68T. doi:10.1144/jgs2021-068. ISSN   0016-7649. S2CID   248647580.
  16. Jørgensen BB (January 1978). "A comparison of methods for the quantification of bacterial sulfate reduction in coastal marine sediments: II. Calculation from mathematical models". Geomicrobiology Journal. 1 (1): 29–47. doi:10.1080/01490457809377722. ISSN   0149-0451.
  17. Berner RA (2020). Early Diagenesis: A Theoretical Approach. Princeton, NJ: Princeton University Press. doi:10.1515/9780691209401. ISBN   978-0-691-20940-1. OCLC   1164642477.

Sources

This page is based on this Wikipedia article
Text is available under the CC BY-SA 4.0 license; additional terms may apply.
Images, videos and audio are available under their respective licenses.